Predictive Control of a Three-Level Boost Converter and an NPC Inverter for High-Power PMSG-Based Medium Voltage Wind Energy Conversion Systems

In this paper, a new medium voltage power converter topology using a diode rectifier, three-level boost (TLB) converter, and neutral-point-clamped (NPC) inverter is proposed for a high-power permanent magnet synchronous generator-based wind energy conversion system. The generator-side TLB converter...

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Published in	IEEE transactions on power electronics Vol. 29; no. 10; pp. 5308 - 5322
Main Authors	Yaramasu, Venkata, Bin Wu
Format	Journal Article
Language	English
Published	New York IEEE 01.10.2014 The Institute of Electrical and Electronics Engineers, Inc. (IEEE)
Subjects	Boost converter Capacitors current control dc-ac power conversion dc-dc power conversion dc-link capacitor voltages balancing digital control diode-clamped converters Diodes direct-driven discrete time signals Electric currents Electrical equipment finite control-set model predictive control (FCS-MPC) gearless grid-connected Inverters Mathematical models medium voltage (MV) megawatt (MW) level multilevel inverters neutral-point-clamped (NPC) converter passive front-end (PFE) permanent magnet synchronous generator (PMSG) Predictive control renewable energy state-space model Switches three-level boost (TLB) converter variable speed Voltage control Wind energy wind energy conversion system (WECS) Wind power Wind turbines
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Abstract	In this paper, a new medium voltage power converter topology using a diode rectifier, three-level boost (TLB) converter, and neutral-point-clamped (NPC) inverter is proposed for a high-power permanent magnet synchronous generator-based wind energy conversion system. The generator-side TLB converter performs the maximum power point tracking and balancing of dc-link capacitor voltages, while the grid-side NPC inverter regulates the net dc-bus voltage and reactive power to the grid. A significant improvement in the grid power quality is accomplished as the NPC inverter no longer controls the dc-link neutral point voltage. A model predictive strategy is proposed to control the complete system where the discrete-time models of the proposed power electronic converters are used to predict the future behavior of control variables. These predictions are evaluated using two independent cost functions, and the switching states which minimize these cost functions are selected and applied to the generator- and grid-side converters directly. In order to comply with the high-power application, the switching frequencies of the TLB converter and NPC inverter are minimized and maintained below 1.5 and 1 kHz, respectively. The proposed topology and control strategy are verified through MATLAB simulations on a 3-MW/3000-V/577-A system and dSPACE DS1103-based experiments on 3.6-kW/208-V/10-A prototype.
AbstractList	In this paper, a new medium voltage power converter topology using a diode rectifier, three-level boost (TLB) converter, and neutral-point-clamped (NPC) inverter is proposed for a high-power permanent magnet synchronous generator-based wind energy conversion system. The generator-side TLB converter performs the maximum power point tracking and balancing of dc-link capacitor voltages, while the grid-side NPC inverter regulates the net dc-bus voltage and reactive power to the grid. A significant improvement in the grid power quality is accomplished as the NPC inverter no longer controls the dc-link neutral point voltage. A model predictive strategy is proposed to control the complete system where the discrete-time models of the proposed power electronic converters are used to predict the future behavior of control variables. These predictions are evaluated using two independent cost functions, and the switching states which minimize these cost functions are selected and applied to the generator- and grid-side converters directly. In order to comply with the high-power application, the switching frequencies of the TLB converter and NPC inverter are minimized and maintained below 1.5 and 1 kHz, respectively. The proposed topology and control strategy are verified through MATLAB simulations on a 3-MW/3000-V/577-A system and dSPACE DS1103-based experiments on 3.6-kW/208-V/10-A prototype.
Author	Bin Wu Yaramasu, Venkata
Author_xml	– sequence: 1 givenname: Venkata surname: Yaramasu fullname: Yaramasu, Venkata email: vyaramas@ee.ryerson.ca organization: Dept. of Electr. & Comput. Eng., Ryerson Univ., Toronto, ON, Canada – sequence: 2 surname: Bin Wu fullname: Bin Wu email: bwu@ee.ryerson.ca organization: Dept. of Electr. & Comput. Eng., Ryerson Univ., Toronto, ON, Canada
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Snippet	In this paper, a new medium voltage power converter topology using a diode rectifier, three-level boost (TLB) converter, and neutral-point-clamped (NPC)...
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SubjectTerms	Boost converter Capacitors current control dc-ac power conversion dc-dc power conversion dc-link capacitor voltages balancing digital control diode-clamped converters Diodes direct-driven discrete time signals Electric currents Electrical equipment finite control-set model predictive control (FCS-MPC) gearless grid-connected Inverters Mathematical models medium voltage (MV) megawatt (MW) level multilevel inverters neutral-point-clamped (NPC) converter passive front-end (PFE) permanent magnet synchronous generator (PMSG) Predictive control renewable energy state-space model Switches three-level boost (TLB) converter variable speed Voltage control Wind energy wind energy conversion system (WECS) Wind power Wind turbines
Title	Predictive Control of a Three-Level Boost Converter and an NPC Inverter for High-Power PMSG-Based Medium Voltage Wind Energy Conversion Systems
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